KR102200724B1 - Artificial cultivation method of seagrasses and Artificial cultivation device - Google Patents

Abstract

The present specification is a first step of germinating by immersing the seeds well; A second step of transplanting the germinated well seed into the sediment; And a third step of controlling the salt concentration of the sediment; and a container; Fresh water in a container; Well-seeds that are soaked in fresh water and selected by analyzing their outer color; And a seawater supply device that supplies seawater to the container.

Description

Artificial cultivation method of seagrasses and artificial cultivation device}

The present invention relates to an artificial cultivation method and an artificial cultivation apparatus of halibut, and more particularly, to an artificial cultivation method and an artificial cultivation apparatus of halibut, which improves the incidence of leaves through selection of cultivated seeds and control of cultivation environment.

Sea grass is a perennial plant that lives on the sea floor and is the only flowering plant that blooms in sea water. They provide spawning, habitat, and shelter for a variety of marine life. In addition, like other plants, it absorbs carbon dioxide and supplies oxygen during photosynthesis to increase the amount of dissolved oxygen. Therefore, the area around the forest is characterized by abundant fish stocks.

There are 9 types of algae found in Korea, and the dominant species is known as leech. Leech horses inhabit a wide range of the west and south coasts, but their habitats are continuously decreasing due to reckless development and environmental pollution. The decrease in the habitat of the alpine does not simply lead to a decrease in the population of the alpine, and the decrease in the number of attached and benthic organisms may cause a decrease in the health of the coastal ecosystem.

In the same vein, the Ministry of Maritime Affairs and Fisheries has set a major policy task to create alpine forests. In addition, government ministries, affiliated research institutes, and private companies are continuing to develop technologies for cultivation and transplantation of alpine, and efforts to solve technical problems found in the creation of alpine forests are continuing.

For example, Korean Patent Registration No. 10-0480526 includes the steps of harvesting seeds of fine blood; Germinating fine seeds; Producing artificial seedlings of Jalpi; The invention relates to a method of artificial cultivation of halibut comprising the step of transplanting artificial seedlings of halibut, characterized in that the artificial cultivation of halibut is utilized in the composition of halibut. However, according to the above patent, the improvement of the germination rate of well seeded seeds is not successful, and there is no suggestion of a specific means for inducing germination of well seeded seeds and the development of leaves.

Korean Patent Registration No. 10-0480526

The present invention has been derived in order to solve the above-described problems, and an object of the present invention is to provide an artificial cultivation method with improved survival rate of Salpi.

In addition, it is an object of the present invention to provide an artificial cultivation apparatus of jappi that can contribute to improving the survival rate of jappi.

The present specification is a means for solving the above-described technical problem, the first step of germinating well seeded by immersion; A second step of transplanting the germinated well seed into the sediment; And a third step of adjusting the salinity of the sediment.

In addition, in the artificial cultivation method of each of the seeds of the present invention, it is preferable to further include a step 0 of selecting the seeds of the well by analyzing the outer color of the seeds of the well.

In addition, in the artificial cultivation method of each of the japonica of the present invention, it is preferable that the first step is performed under fresh water conditions.

In addition, in the artificial cultivation method of each of the salpis of the present invention, it is more preferable that the third step is sequentially increasing the salinity concentration until the salinity concentration of the sediment reaches 35 psu.

Further, in the artificial cultivation method of each of the skins of the present invention, it is preferable that the sediment contains fine yarn.

In addition, in the artificial cultivation method of each of the japonica of the present invention, the sediment contains fine yarn and medium yarn, and it is preferable that the ratio of the fine yarn is 50% by weight or more.

On the other hand, the present specification is a container; Fresh water in a container; Well-seeds that are soaked in fresh water and selected by analyzing their outer color; And a seawater supply device for supplying seawater to the container.

In addition, in the artificial cultivation apparatus of each of the salpis of the present invention, it is preferable that the seawater supply apparatus supply seawater so that the salinity concentration of the sediment can be increased sequentially until the salinity concentration of the sediment reaches 35 psu.

The artificial cultivation method of halibut of the present invention provides an artificial cultivation method capable of improving the survival rate of halibut by controlling the germination environment and adaptation conditions.

In addition, the present invention provides an artificial cultivation apparatus capable of improving the survival rate of the algae by controlling the germination environment and adaptation conditions of the almond.

1 is a photograph taken by classifying well-seeds into four groups according to their moisture content.
Figure 2 shows the germination rate of fine seeds according to the salt concentration.
3 shows the ratio of appearance of small roots according to the salt concentration and the type of sediment.
FIG. 4 shows the germination rate, small root appearance rate, and leaf growth rate according to the type of sediment when a change in salt concentration is induced.

The terms used in the present application are only used to describe specific examples. So, for example, a singular expression includes a plural expression unless the context clearly has to be singular. In addition, terms such as "include" or "include" used in the present application are used to clearly refer to the existence of features, steps, functions, components or combinations thereof described in the specification, but other features It should be noted that it is not used to preliminarily exclude the presence of elements, steps, functions, components, or combinations thereof.

Meanwhile, unless otherwise defined, all terms used in this specification should be viewed as having the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs. Therefore, unless clearly defined in the specification, specific terms should not be interpreted in an excessively ideal or formal sense.

<1. Artificial cultivation method of walnut of the present invention>

The present specification, the first step of germinating well by immersion in seeds; A second step of transplanting the germinated well seed into the sediment; And a third step of adjusting the salinity of the sediment. In addition, in the artificial cultivation method of each of the seeds of the present invention, it is preferable to further include a step 0 of selecting the seeds of the well by analyzing the outer color of the seeds of the well. Hereinafter, each step will be classified and described in detail.

<1.1. Selection of fine seeds>

In the artificial cultivation method of each of the skin of the present invention, it is preferable to further include a step 0 of selecting the seed of the well by analyzing the outer color of the seed. By analyzing the outer color of the seed seed, the moisture content of the seed seed can be estimated. As the water content is higher, the seed seeds tend to be light brown, and the lower the moisture content is, the more they tend to be pale green. That is, the outer color of the seedlings gradually changes from light green to dark green, greenish brown, and light brown in order as the moisture content increases.

1 is a photograph taken by classifying fine seeds into four groups according to their moisture content. Referring to FIG. 1, it can be seen that they are classified in the order of light green (A), dark green (B), green brown (C), and light brown (D). On the other hand, the researchers confirmed that the germination rate of well-seeds with similar outer color appeared constant.

Specifically, according to the observations of the researchers, seeds belonging to light brown (D) have the lowest germination rate, and seeds belonging to dark green (B) have the highest germination rate. In the case of seeds belonging to dark green (B) and seeds belonging to green brown (C), there is a slight difference, and in the case of seeds belonging to dark green (B) and those belonging to light green (A), there is a significant difference.

The weight, moisture content, and germination rate of specific seeds of each group are shown in Table 1 below. The moisture content is a value measured based on the following formula. Drying is preferably performed in a dry oven at 60° C. for 3 days. The germination conditions will be described later.

Seed color Seed weight (mg) Moisture content (%) Germination rate (%) Light green (A) 13.66 ± 0.68 38.50 ± 0.42 80.00 ± 1.09 Dark green (B) 13.25 ± 0.52 44.71 ± 2.94 90.00 ± 3.46 Green brown (C) 11.75 ± 0.25 50.62 ± 2.21 88.67 ± 1.15 Light brown (D) 10.83 ± 0.42 71.11 ± 0.59 51.33 ± 4.06

<1.2. Germination conditions of well seeded seeds>

In addition, in the artificial cultivation method of each of the japonica of the present invention, it is preferable that the first step is performed under fresh water conditions. In particular, it is more preferable to germinate the well-seeds selected according to the surface color in step 0 under fresh water conditions. The present invention is characterized in that the surface color is analyzed in order to easily determine the moisture content.

On the other hand, the germination rate in freshwater conditions is considered to have a close correlation between the moisture content and the seed weight. In particular, when inducing germination under fresh water conditions, the moisture content of the seed seed is preferably between 10% and 70%. A positive correlation is established between the germination rate and the moisture content below a certain rate. When the moisture content of the well seeded seeds is less than 10%, germination does not occur at a significant rate. Conversely, when the moisture content is 70% or more, the osmotic pressure caused by exposure to fresh water of the well seed is generated above a certain level, and as shown in [Table 1], a rapid decrease in the germination rate can be confirmed.

Furthermore, from the viewpoint of ensuring a high germination rate, it is more preferable that the moisture content of the seed seed is between 30% and 60%. In addition, it is most preferable that the moisture content of well seeded seeds is between 35% and 55% in that a germination rate of 80% or more can be guaranteed.

On the other hand, even if the germination of the seedling is induced under freshwater conditions, the rate of growing as a young leaf is not high, and in some cases, the seedling may die due to the propagation of fungi. Accordingly, another feature of the present invention is to provide a methodology capable of successfully growing seedlings germinated under freshwater conditions until the leaves appear. Regarding this, the following <1.3. It will be described in detail in the conditions of appearance of small piriformis roots and development of leaves.

On the other hand, when applying the conditions for appearance and development of leaf leaves of the present invention, in the artificial cultivation method of each of the present invention, the sediments are fine sand, medium sand, and compost ( It is preferable to include at least one selected from the group consisting of 堆肥, Compost).

In the present invention, the sediment is constructed using a standard body. [Table 2] shows the detailed composition of each of the fine sand, middle sand, and compost (堆肥, Compost).

Composition of sediment Grain size 250-650μm 63-250μm <63 μm Severe conditions 72.93 ± 1.33 27.06 ± 1.34 0.00 ± 0.00 Fine condition 13.77 ± 2.18 77.60 ± 1.59 8.63 ± 0.71 Compost conditions 46.90 ± 4.11 47.83 ± 3.95 5.27 ± 0.64

In the absence of sediment, the rate of emergence of small stalks was relatively high, but the rate of incidence of leaflets decreased rapidly. Therefore, in order to induce the growth of the larvae, it is considered that the conditions in which sediments are present are preferable.

On the other hand, in the artificial cultivation method of each of the skins of the present invention, the sediment contains fine yarn and medium yarn, and it is more preferable that the ratio of the fine yarn is 50% by weight or more. When the above-described sediment conditions and other conditions are satisfied, it can be confirmed that most of the emerged papillaris grow into leaves, and the incidence rate of the first leaves exceeds about 15%. Hereinafter, more detailed description will be given with respect to the conditions for the appearance and the development of the leaves.

<1.3. Conditions for emergence and development of young leaves>

In the artificial cultivation method of each of the japonica of the present invention, in the third step, it is preferable to increase the salinity concentration in sequence until the salinity concentration of the sediment reaches 35 psu. At this time, in sequentially increasing the salt concentration, it is necessary to provide a sufficient adaptation time under a specific hydration condition so that the seedlings germinated in fresh water can adapt to the function.

Particularly, as an embodiment of the present invention, in the third step, it is more preferable to increase the salt concentration by about 5 psu every 48 hours. When the salinity concentration was increased by about 5 psu at intervals of 48 hours, the emergence of small roots and leaflets were successfully formed within 21 days from the germinated seedlings. That is, one of the key problem solving principles of the present invention is to allow the well-seeds germinated under freshwater conditions to gradually undergo an adaptation period to the salt concentration for a sufficiently long time so that they can grow successfully as adults.

However, in the method of increasing the salt concentration, it should be noted that the third step of the present invention is not necessarily limited to the method of increasing the salt concentration to a certain degree at regular intervals. A method of increasing the salt concentration to a certain degree at irregular intervals, a method of increasing the salt concentration to an irregular degree at regular intervals, and a method of increasing the zero degree of irregularity at irregular intervals are all possible. For example, as an example, it is possible that the increase in the salt concentration during the late 10 days is larger than the increase in the salt concentration during the first 10 days.

Further, in the artificial cultivation method of each of the skins of the present invention, it is preferable that the sediment contains fine yarn. In addition, in the artificial cultivation method of each of the skins of the present invention, the sediment includes fine yarn and medium yarn, and it is preferable that the ratio of the fine yarn is 50% by weight or more. When the above-described sediment conditions are satisfied, it can be confirmed that most of the emerged zygomatic roots grow into leaves, and the incidence rate of the first leaves exceeds about 15%.

Specifically, when the salinity conditions were sequentially increased and compared based on the same point of time, the appearance of zymophilus was the highest in the fine thread condition. Next, in the mixed yarn condition of 50% by weight of fine yarn and heavy yarn, the emergence rate of Jalpiso Geun was high, and in the condition of heavy yarn, the appearance rate of Jalpiso Geun was low. On the other hand, in conditions containing compost, the appearance of small roots occurs very slowly.

Furthermore, when the ratio of fine thread and medium thread is included, and the ratio of fine thread is 50% by weight or more, the incidence rate of one leafy leaf and the occurrence rate of two leaflets appear higher than that of other sediment conditions. In particular, the rate of occurrence of one leaf in the fine yarn condition exceeds 20%. In particular, when the ratio of fine yarn is 100% by weight, it appears that the rate of occurrence of one leaf and the rate of occurrence of two leaves are the highest.

<2. Artificial cultivation device of jalpica of the present invention>

The present specification is a container; Fresh water in a container; Well-seeds that are soaked in fresh water and selected by analyzing their outer color; And a seawater supply device for supplying seawater to the container.

In the artificial cultivation apparatus of the present invention, the seed seed selected by analyzing the annoying outer color means a seed seed whose outer color is pale green (A), dark green (B), or green brown (C). Regarding the outer color of fine seeds, the above <1.1. Selection of fine seed> applies mutatis mutandis.

On the other hand, in the artificial cultivation apparatus of the present invention, the cultivation environment is improved by using the already selected fine seed, but in some cases, a device capable of selecting the fine seed based on the outer color of the fine seed is further provided. It is possible to include. In addition, the screening of the sorting device may be a screening for well seeded seeds having a high moisture content, conversely, may be screening for a well seeded seed with a low water content. In the former case, impregnation of the selected seeds may be involved, and in the latter case, disposal of the selected seeds may be involved.

In addition, in the artificial cultivation apparatus of each of the salpis of the present invention, it is preferable that the seawater supply apparatus supply seawater so that the salinity concentration of the sediment can be increased sequentially until the salinity concentration of the sediment reaches 35 psu.

However, it should be noted that the seawater supply device of the present invention is not limited to a device that increases the salt concentration to a certain degree at regular intervals. It is possible to increase the salt concentration to a certain degree at irregular intervals, to increase the salt concentration to an irregular degree at regular intervals, or to increase the zero-minority to an irregular degree at irregular intervals.

On the other hand, the artificial cultivation apparatus of Jalpi of the present invention may further include a separate seawater storage device for supplying seawater to the seawater supply device. In addition, the seawater storage device may further include a salinity meter that measures the salt concentration of seawater, and a sterilizer that can sterilize the seawater at all times. By using the seawater storage device including the salinity meter and the sterilizer, it is possible to uniformly maintain the cultivation conditions in the artificial cultivation apparatus of the present invention, and furthermore, it is possible to prevent the death of the incidental seeds.

Hereinafter, what is claimed by the present specification will be described in more detail with reference to the accompanying drawings and embodiments. However, the drawings or examples presented in the present specification may be modified in various ways by a person skilled in the art to have various forms, and the description of the present specification is not limited to a specific disclosure form. It should be viewed as including all equivalents or substitutes included in the spirit and scope of the present invention. In addition, the accompanying drawings are presented to help a person skilled in the art understand the present invention more accurately, and may be exaggerated or reduced than in actuality.

{Examples and evaluation}

Example 1a. Freshwater conditions

Dark green (B) well seeded seeds were selected and prepared. The seed seed was impregnated in fresh water (0 psu) and the germination rate was measured.

Comparative Example 1a. First function condition

Dark green (B) well seeded seeds were selected and prepared. The fine seed was impregnated with water (15 psu) and the germination rate was measured. The water was prepared by mixing sterile seawater and fresh water.

Comparative Example 1b. 2nd function condition

Dark green (B) well seeded seeds were selected and prepared. The fine seed was impregnated with water (30 psu) and the germination rate was measured. The water was prepared by mixing sterile seawater and fresh water.

Evaluation 1. Germination evaluation according to salt concentration

Figure 2 shows the germination rate of fine seeds according to the salt concentration. Referring to FIG. 2, it can be seen that the germination rate of well seeded seeds is the highest in the hydrated condition. Specifically, it was observed that 89.33% of seeds germinated under the hydrated condition. In addition, it can be seen that as the salt concentration increases, the germination rate decreases. Through this, it can be confirmed that the occurrence of stimulation required for germination of well seeded seeds is not sufficient under the hydrated condition.

Example 2a. Specific adaptation conditions and fine yarn conditions

The fine seeds germinated in Example 1a were transplanted into the sediment. The sediment contained 100% by weight of fine yarn. Seawater was added at intervals of 48 hours to increase the salinity concentration of the sediment by about 5 psu.

More specifically, after germinating the seedlings under the water condition for 72 hours, the seedlings were cultivated under the water condition of 5 psu for 48 hours. Thereafter, seawater was further added so that the water was 10 psu, followed by cultivation for 48 hours. In the same way, well seeded seeds were grown for 48 hours each in the water condition of 15 psu, 20 psu, 25 psu, and 30 psu. A total of 15 days elapsed from 0 psu to 30 psu. Finally, well-seeds were grown under water conditions of 35 psu for 120 hours.

Example 2b. Mixed yarn condition

Other conditions were the same as in Example 2a, but the sediment contained 50% by weight of fine yarn and 50% by weight of medium yarn.

Example 2c. Severe conditions

Other conditions were the same as in Example 2a, but the sediment contained 100% by weight of heavy sand.

Comparative Example 2a. 1st composting condition

Other conditions were the same as in Example 2a, but the sediment contained 50% by weight of heavy sand and 50% by weight of compost.

Comparative Example 2b. 2nd composting condition

Other conditions were the same as in Example 2a, but the sediment contained 50% by weight of fine yarn and 50% by weight of compost.

Evaluation 2. Growth evaluation according to salinity and sediment conditions

3 shows the rate of appearance of small roots according to the salt concentration and the type of sediment. The control group is the soil free condition. On the 10th day, it was confirmed that small roots appeared from 25.00% (Example 2a), 20.00% (Example 2b), and 11.67% (Example 2c) fine seeds, respectively, in Examples 2a to 2c. Likewise, it was confirmed that small roots appeared from 28.33% (Example 2a), 23.33% (Example 2b), and 20.00% (Example 2c) fine seedlings in Examples 2a to 2c, respectively. That is, by taking the conditions of Examples 2a to 2c, it is possible to enjoy a small root appearance rate exceeding 20%.

On the other hand, in the case of Comparative Examples 2a and 2c, the small root appearance rate was measured at the same time, but 1.67% (Comparative Example 2a, Day 10), 1.67% (Comparative Example 2b, Day 10), 6.67% (Comparative Example 2a, It can be seen that the 10th day), 5.00% (Comparative Example 2b, 10th day).

FIG. 4 shows the germination rate, small root appearance rate, and leaf growth rate according to the type of sediment when a change in salt concentration is induced. Specifically, FIG. 4 shows the germination ratio, small root emergence ratio, the incidence ratio of one leaflet, and the incidence ratio of two leaflets in Examples 2a to 2c and Comparative Examples 2a to 2b (day 21, the control group It is a soil absence condition).

When only the germination ratio is considered, it can be confirmed that the largest number of well seeded seeds reached germination in Comparative Example 2a. Therefore, it is possible to consider the soil condition of Comparative Example 2a as the first soil condition, assuming transplantation of well seeded seeds. However, it can be seen that the soil conditions of Comparative Example 2a are unfavorable compared to Examples 2a to 2c of the present invention when viewed from the viewpoint of the emergence of zygomatic roots and the development of zygomatic leaves.

In other words, it was observed that the soil conditions of Examples 2a to 2c of the present invention induce the appearance of small roots and provide an environment suitable for the establishment of small roots and the development of leaves. Particularly, in the case of Example 2a, the highest incidence rate was shown. In addition, it was found that Example 2b also had a statistically significant difference compared to other conditions from the viewpoint of the incidence of perilla leaf leaves. Since the common point between Example 2a and Example 2b can be said to be the presence of fine yarn, it can be inferred that when the fine yarn is more than a certain ratio, the rate of appearance of the perilla leaves can be improved.

Therefore, the sediment contains fine yarn and heavy yarn, and it is more preferable that the ratio of the fine yarn is 50% by weight or more. When the above-described sediment conditions are satisfied, it can be confirmed that most of the emerged zygomatic roots grow into leaves, and the incidence rate of the first leaves exceeds about 15%.

Claims (8)

delete delete delete delete delete delete A device capable of selecting fine seed based on the outer color of the seed seed;
A first container with fresh water;
A second container with sediment; And
Includes; a seawater supply device for supplying seawater to the second container,
The moisture content of the fine seed selected by the device is 30% to 60%,
The selected fine seed is germinated in the first container and then transplanted into the sediment in the second container,
The sediment is an artificial cultivation apparatus of Jalpi, characterized in that the sediment includes fine thread and medium thread, and the ratio of the fine thread is 50% by weight or more.
The method of claim 7,
The seawater supply device is an artificial cultivation apparatus of Jalpi, characterized in that it supplies seawater to increase the salinity concentration sequentially until the salinity concentration of the sediment reaches 35 psu.

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